Understanding Eigenvectors and Eigenvalues

They require a strong visual understanding of prior topics.

They are not well explained in textbooks.

They involve complex numbers.

They are not applicable in real-world scenarios.

It disappears.

It changes direction but not magnitude.

It gets rotated off its span.

It remains on its span and is scaled by a factor.

The angle of rotation.

The factor by which an eigenvector is scaled.

The number of dimensions reduced.

The determinant of the matrix.

It confirms the matrix is diagonal.

It indicates a non-zero eigenvector exists.

It ensures the matrix is invertible.

It shows the matrix has no solutions.

It is subtracted from the matrix to find eigenvalues.

It rotates the eigenvectors.

It adds complexity to the matrix.

It scales the eigenvectors by zero.

It scales vectors by zero.

It only has complex eigenvalues.

It has a determinant of zero.

It rotates vectors off their span.

The matrix has no real solutions.

The matrix scales all vectors by the same factor.

The matrix is not invertible.

The matrix is a rotation matrix.

A matrix with non-zero entries only off the diagonal.

A matrix with equal rows and columns.

A matrix with non-zero entries only on the diagonal.

A matrix with all zero entries.

By allowing the matrix to be expressed as a sum of vectors.

By reducing the matrix to a single row.

By making the matrix non-invertible.

By converting the matrix into a diagonal form.

It allows for easy inversion.

It simplifies the computation of matrix powers.

It eliminates the need for eigenvectors.

It reduces the matrix to a single value.